Passive enhanced moca entry device

ABSTRACT

The present disclosure is directed to a passive, enhanced MoCA entry device. The entry device includes an entry port, a broadband port, high-band ports, and a filter device. The entry device also includes a broadband path connecting the entry port to the broadband port and a high-band path connecting the entry port to the plurality of high-band ports. The filter device generates a broadband signal and a high-band signal. The filter device provides the broadband signal to broadband port via the broadband path. And, the filter device provides the high-band signal to the high-band ports via the high-band path.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional Patent ApplicationNo. 62/356,937, filed Jun. 30, 2016, the content of which isincorporated herein in its entirety.

FIELD

This invention generally relates to cable television (CATV) networks andto in-home entertainment networks. More particularly, the presentinvention relates to a Multimedia over Coax Alliance (MoCA) entrydevice.

BACKGROUND

CATV networks supply and distribute high frequency “downstream” signalsfrom a main signal distribution facility, known as a “headend,” topremises (e.g., homes and offices) of subscribers. The downstreamsignals can be provided to subscriber equipment, such as televisions,telephones, and computers. In addition, most CATV networks also receive“upstream” signals from subscriber equipment back to the headend of theCATV network. For example, a set top box can send an upstream signalincluding information for selecting programs for viewing on atelevision. Also, upstream and downstream signals are used by personalcomputers connected through the CATV infrastructure to the Internet.Further, voice over Internet protocol (VOIP) telephones use upstream anddownstream signals to communicate telephone conversations.

To permit simultaneous communication of upstream and downstream CATVsignals, and to permit interoperability of the subscriber equipment andthe equipment associated with the CATV network infrastructure outside ofsubscriber premises, the downstream and upstream signals are confined totwo different frequency bands. For example, in some CATV networks thedownstream frequency band can be within the range of 54-1002 megahertz(MHz) and the upstream frequency band can be within the range of 5-42MHz.

The downstream signals are delivered from the CATV networkinfrastructure to the subscriber premises at a CATV entry device, whichis also commonly referred to as a network interface device, an entryadapter, a port adapter, or a drop amplifier. The entry device is amulti-port device that connects at an entry port to a CATV drop cablefrom the CATV network infrastructure and connects at a multiplicity ofother input/output ports (hereinafter “ports”) to coaxial cables thatextend throughout the subscriber premises to cable outlets. Each cableoutlet is available to be connected to subscriber equipment such astelevision sets, computers, and telephone sets. The multiple ports ofthe entry device deliver the downstream signals to each cable outlet andconduct the upstream signals from the subscriber equipment through theentry device to the drop cable of the CATV infrastructure.

In addition to television sets, computers and telephones, a large numberof other entertainment and multimedia devices are available for use inhomes. For example, a digital video recorder (DVR) can be used to recordbroadcast programming, still photography and movies in a memory mediumso that the content can be replayed on a display or television set at alater time selected by the user. As another example, video games arealso played on personal computers or on gaming systems connected totelevision sets. Such video games may be those that interface real timethrough the CATV network's internet service provider. As a furtherexample, signals from a receiver of satellite-broadcast signals may bedistributed for viewing or listening throughout the home. These types ofdevices, which can also include conventional television sets, telephonesets, and other such devices connected to the Internet by the CATVnetwork, are generically referred to as “multimedia devices.”

The desire to use multimedia devices at multiple different locationswithin the home or subscriber premises has led to the creation of MoCA.MoCA has developed specifications for products to create an in-homeentertainment network for interconnecting multimedia devices. A MoCAin-home network uses the subscriber premise or in-home coaxial cableinfrastructure originally established for distribution of CATV signalswithin the subscriber premises, principally because that coaxial cableinfrastructure already exists in most homes and is capable of carryingmuch more information than is carried in the CATV frequency bands. AMoCA network is established by connecting MoCA-enabled or MoCA interfacedevices at the cable outlets in the rooms of the subscriber premises.These MoCA interface devices implement a MoCA communication protocolwhich encapsulates signals normally used by the multimedia deviceswithin MoCA signal packets and then communicates the MoCA signal packetsbetween other MoCA interface devices connected at other cable outlets.The receiving MoCA interface device removes the encapsulated multimediasignals from the MoCA signal packets, and delivers the multimediasignals to the connected display, computer, or other multimedia devicefrom which the content is presented to the user.

Each MoCA-enabled device is capable of communicating with every otherMoCA-enabled device in the subscriber premises to deliver the multimediacontent. For example, the multimedia content that is available from oneMoCA-enabled device can be displayed, played, or otherwise used on adifferent MoCA-enabled device at a different location within thesubscriber premise, thereby avoiding physically relocating theoriginating multimedia device from one location to another within thesubscriber premises. The communication of multimedia content over theMoCA network is beneficial because it more fully utilizes the multimediadevices present in modern homes.

In current entry devices for MOCA networks, the outputs on thedownstream side communicate over the frequency range of 54 MHz to 1675MHz. Accordingly, components of the MOCA entry device (e.g., filters andsplitters) are configured to operate over this entire frequency range.However, doing so prevents the components from being optimized for anyparticular operating range, which reduces the performance (e.g., noise,power loss, and/or isolation) of the components while increasing theircost and/or complexity.

SUMMARY

Embodiments in accordance with the present disclosure provide a passiveMoCA entry device including an entry port that communicates CATV signalswith a provider. The device also includes a broadband port thatcommunicates the CATV signals with a gateway device at a premises. Thedevice further includes high-band ports that communicate MoCA signalswith MoCA devices at the premises. Additionally, the device includes alow-band filter that blocks the MoCA signals from the entry port.Moreover, the device includes a broadband path connecting the broadbandport to the entry port and the high-band port. The broadband pathcommunicates the CATV signals between the broadband port and the entryport, and communicates the MoCA signals between with the broadband portand the high-band ports. Further, the device includes a high-band pathconnecting the high-band ports to the broadband port. The high-band pathpasses only the MoCA signals to the high-band ports.

Additionally, embodiments in accordance with the present disclosureprovide a RF entry device including a filter device that communicateslow-band RF signals with an entry port. The device also includes abroadband path that communicates broadband RF signals with a broadbandport. The device also includes a high-band path that communicateshigh-band RF signals with high-band ports. The filter device blockscommunication of any RF signals having frequencies greater than afrequency band of the low-band RF signals. The high-band path rejectsany RF signals having frequencies less than a frequency band of thehigh-band RF signals. And, the broadband path passes RF signals havingfrequencies in the frequency bands of the low-band RF signals and thehigh-band RF signals.

Further, embodiments in accordance with the present disclosure provide adevice including an entry port, a broadband port, high-band ports, and afilter device. The device also includes a broadband path connecting theentry port to the broadband port, and a high-band path connecting thebroadband port to the high-band ports. The broadband path provides alow-band signal from the broadband port to the filter device. Thehigh-band path provides a high-band signal to the broadband path andrejects the low-band signal from the broadband path. The filter deviceblocks frequencies of the high-band signal . . . .

It will be appreciated that this summary is intended merely to introducesome aspects of the present methods, systems, and media, which are morefully described and/or claimed below. Accordingly, this summary is notintended to be limiting.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute apart of this specification, illustrate embodiments of the presentteachings and together with the description, serve to explain theprinciples of the present teachings.

FIG. 1 shows a block diagram illustrating an example of an environmentfor a MoCA entry device in accordance with aspects of the presentdisclosure.

FIG. 1A shows a block diagram illustrating an example of an environmentfor a MoCA entry device in accordance with aspects of the presentdisclosure.

FIG. 2 shows a block diagram of an example of a MoCA entry device inaccordance with aspects of the present disclosure.

FIG. 3 shows a block diagram of an example of a MoCA entry device inaccordance with aspects of the present disclosure.

FIG. 4 shows a block diagram of an example of a MoCA entry device inaccordance with aspects of the present disclosure.

FIG. 5 shows a block diagram of an example of a MoCA entry device inaccordance with aspects of the present disclosure.

FIG. 6 shows a block diagram of an example of a MoCA entry device inaccordance with aspects of the present disclosure.

FIG. 6A shows a block diagram of an example of a reflection filter inaccordance with aspects of the present disclosure.

DETAILED DESCRIPTION

The present disclosure is directed to a passive MoCA entry device thatsplits signals into two paths and distributes the signals to broadbanddevices (e.g., CATV devices such as VOIPs, embedded multimedia portadapters (“eMTAs”), cable modem/gateways, and/or master DVR devices) ina broadband path, and high-band devices (e.g., multimedia devices) in ahigh-band path. In accordance with aspects of the present disclosure,components (e.g., resistors, capacitors, and inductors) used in circuitswithin the broadband path and the high-band path are optimized totransfer the frequencies of signals respectively carried by the paths.The optimization of the circuits tuned to the broadband path and thehigh-band path using high-precision components having physicalconfigurations (size, core, and/or coils) that minimize loss (dB) in theoperating frequency ranges of the paths, maximizes loss (dB) outside theoperating frequency ranges of the paths, and minimizes reflectionsand/or sideband interference of the signals. By doing so, the circuitsincluded each the broadband path and the high-band path can besimplified to reduce the cost of the MoCA entry device, as well as thatof the multimedia devices in a subscriber premises.

Additionally, some embodiments of the MoCA entry device disclosed hereinminimize a number of ports for the broadband devices. For example, theMoCA entry device may only include one broadband port, and some otherembodiments may include only two broadband ports. As splitting of thebroadband signal among a number of broadband ports is avoided, the MoCAentry device minimizes degradation (e.g., power loss) of the broadbandsignal. Thus, MoCA entry device disclosed herein is optimal forarchitectures that use a single modem/gateway device (e.g., a CATVset-top box) capable of communicating with both broadband devices in theCATV band (e.g., 5-1002 MHz) and high-band devices the MoCA frequencyband (e.g., 1125-1675 MHz). Such modem/gateway device permitsinformation that is transmitted by a service provider (e.g., a CATVsystem) to be shared amongst device in a MoCA network of a subscriber bypermitting information included in the source signal (e.g., the CATVband) to be rebroadcast within the MoCA network.

FIG. 1 shows a block diagram illustrating an example environment 10 inaccordance with aspects of the present disclosure. The environment 10includes a MoCA entry device 100, a premises 103, and a headend 107. TheMoCA entry device 100 can be installed between the premises 103 (e.g., ahome or business of a CATV subscriber) and a cable (e.g., COAX cable)connecting the headend 107 (e.g., an infrastructure of a CATV servicethat provides high-definition multimedia content and broadband Internetservice). The MoCA entry device 100 includes an entry port 111, one ormore broadband ports 113A and 113B (e.g., CATV ports), and amultiplicity of high-band ports 115 (e.g., MoCA ports), a filter device117, a broadband path 125, and a high-band path 127.

The entry port 111 can connect to the headend 107 from which itreceives/transmits a source signal 116 having a CATV frequency band (C).In embodiments, the CATV frequency band (C) can have a range betweenabout 5 MHz to about 1002 MHz (e.g., a CATV signal). For example, theheadend can be part of the infrastructure of a CATV service provider andthe entry port 111 can connect to a drop cable of the CATV serviceprovider. While FIG. 1 illustrates a signal entry port, it is understoodthat the MoCA entry device 100 can include two or more entry ports 111which receive respective source signals 116 that are combined by asplitter/combiner device and provided to the filter device 117.

The filter device 117 connects the entry port 111 to the broadband path125 and the high-band path 127. In accordance with aspects of thepresent disclosure, the filter device 117 receives the source signal 116from the entry port 111 and passes it to the broadband path 125, whileblocking the source signal 116 from the high-band path 127. In someembodiments, the filter device 117 is a diplexer having a low-bandfilter 119 and a high-band filter 121. The low-band filter 119 can beconfigured to bidirectionally pass the CATV frequency band (C) of thesource signal 116 between the entry port 111 and the broadband path 125and reject any frequencies greater than the CATV frequency band (C). Forexample, the low-band filter 119 can reject frequencies greater thanabout 1000 MHz (e.g., above the CATV band). Additionally, the high-bandfilter 121 of the filter device 117 can be a high-pass filter configuredto reject all frequencies less than about 1125 MHz (e.g., frequenciesbelow the MoCA band), which includes the CATV frequency band (C) of thesource signal 116. In some embodiments, the high-band filter 121 can bea band-pass filter that rejects frequencies of the CATV signal 116outside range of about 1125 MHz to about 1675 MHz. As such, thehigh-band filter 121 blocks communication of the source signal 116 fromthe filter device 117 to the high-band path 127.

The broadband path 125 and the high-band path 127 are physical,conductive (e.g., wired) signal paths. In accordance with aspects of thepresent disclosure, the broadband path 125 connects between the filterdevice 117 and the broadband ports 113A and/or 113B, and bidirectionallycommunicates broadband signal 123 to/from a gateway device 135 (e.g., aCATV gateway devices, such as a set-top box) and/or a broadband device136 (e.g., a modem) in the premises 103. The broadband signal 123 canhave a range between about 5 MHz to about 1675 MHz, which includes theCATV frequency band (C) of the source signal 116 (e.g., about 5 MHz-1002MHz) and a high frequency band (M) (e.g., the MoCA band) of high-bandsignal 124 (e.g., about 1125 MHz-1675 MHz). In some embodiments, thebroadband path 125 includes a broadband splitter 129, which splits thebroadband signal 123 provided downstream from the filter device 117 andfeeds it to the broadband ports 113A and 113B. Additionally, in theupstream direction, the broadband splitter 129 can combine broadbandsignals 123 from the gateway device 135 and/or the broadband device 136into a composite signal. Notably, the hashed lines of broadband port113B and broadband device 136 indicate that they are optional. And, asdescribed previously herein, some embodiments of the MoCA entry device100 may only include a single broadband port 113A for connection to asingle broadband device, which may be the gateway device 135 thatnetworks with high-band devices 137 in the premises 103 (e.g., in a MoCAnetwork).

The broadband splitter 129 can be ferrite, resistive, or transmissionline splitter. In accordance with aspects of the present disclosure, thebroadband splitter 129 is configured to operate only at frequencies atand below about 1675 MHz by, for example, using components (e.g.,resistors, capacitors, inductors) that minimize noise, reflection, powerloss, leakage, etc. over the frequency range of the broadband path 125.In some embodiments, the broadband path 125 lacks any splitter, such asbroadband splitter 129. Instead, a single broadband downstream port 113Aconnects directly to the filter device 117 via transmission lineswithout any intervening splitter, combiner directional coupler, orsimilar component. In such embodiments, the transmission lines can beoptimized to operate at frequencies at and below about 1675 MHz.

The high-band path 127 connects the broadband downstream ports 113 tothe high-band ports 115, and bidirectionally communicates high-bandsignals 124 having a high frequency band (M) (e.g., MoCA band signals)from the gateway device 135 and/or the broadband device 136 to one ormore high-band devices 137 (e.g., MoCA devices) in the premises 103, andvice versa. The high-band path 127 includes high-band splitter 131,which a one or more devices configured to receive the high-band signal124 (e.g., a high-band component of the broadband signal 123) from thefilter device 117 (e.g., high-band filter 121) as an input, split suchsignal, and output it to the high-band ports 115. In the reversedirection, the high-band splitter 131 is configured to receive a numberof high-band signals 124 as inputs to a two or more terminals, combinesuch signals into a composite high-band signal 124, and output thecomposite high-band signal 124 to the filter device 117.

The high-band splitter 131 can include one or more ferrite, resistive,or transmission line splitters. In accordance with aspects of thepresent disclosure, components of the high-band splitter 131 can beoptimized for the frequencies of the high-band signal 124. Additionally,the high-band splitter 131 operate only at frequencies at or above 1000MHz using components that minimize noise, reflection, power loss,leakage etc. over the frequency range of the high-band path 127. In someembodiments, the high-band splitter 131 operate only at frequencies ator between 1100 MHZ and 2000 MHz. Additionally, in some embodiments, thecomponents of the high-band splitter 131 are optimized to operate onlyat frequencies at or between 1125 MHZ and 1675 MHz

Referring now to the signal flow of the MoCA entry device 100 from entryport 111 to the broadband ports 113A and/or 113B, the entry port 111 canreceive the source signal 116 from the headend 107 via the entry port111, which can be connected to the low-band filter 119 of the filterdevice 117. The low-band filter 119 can pass the source signal 116 tothe broadband port 113A via the broadband path 125. In some embodiments,the broadband path 125 includes a broadband splitter 129 the divides thesource signal 116 and provides it to broadband ports 113A and 113B, aspreviously described.

Referring now to the signal flow of the MoCA entry device 100 from theentry port 111 to the downstream high-band ports 115, the entry port 111can receive a source signal 116 as described above. However, thehigh-band filter 121 blocks the CATV frequency band (C) of the sourcesignal 116, which prevents the source signal 116 from passing to thedownstream high-band ports 115. Rather, the source signal 116 can onlyflow downstream to the downstream broadband ports 113A and/or 113B.

Referring now to the signal flow of the MoCA entry device 100 from thebroadband ports 113A and/or 113B to the entry port 111, the broadbandports 113A and/or 113B can receive the broadband signal 123 from thegateway device 135 and/or the broadband device 136. As describedpreviously herein, the broadband signal 123 can have a range betweenabout 5 MHz to about 1675 MHz, which includes a CATV frequency band (C)component and a high frequency band (M) component. The broadband path125 receives the broadband signal 123 as an input from broadband ports113A and/or 113B and provides it to the filter device 117. In someembodiments, the broadband splitter 129 in the broadband path 125combines the broadband signals 123 received from the gateway device 135and the broadband device 136. As described previously herein, thelow-band filter 119 of the filter device 117 only passes the CATVfrequency band (C) of the broadband signal 123 upstream to the entryport 111. Accordingly, the filter device 117 blocks the high frequencyband (M) component of the broadband signal 124 from passing to the entryport 111. The filter device 121 permits high frequency band (M) of thebroadband 123 to pass to the high-band path 127.

Referring now to the signal flow of the MoCA entry device 100 from thebroadband ports 113A and 113B to high-band ports 115, the broadbandports 113A and 113B and the broadband path 125 can receive the broadbandsignal 123 and pass such signal to the filter device 117 as describedpreviously herein. However, as detailed above, the high-band filter 121blocks the CATV frequency band (C) component of the broadband signal 123from passing to the high-band path 127. Instead, in some embodiments,the high-band filter 121 only passes frequencies above the CATVfrequency band (C). for example, the high-band filter 121 may only passthe high frequency band (M) to the high-band path 127 and rejects allfrequencies outside such band. In some other embodiments, the filterdevice 117 does not include the high-band filter, and the CATV frequencyband (C) is substantially or entirely rejected by frequency-selectivecomponents (e.g., transmission lines and splitters) of the high-bandsplitter 131. Accordingly, the filter device 117 blocks the CATVfrequency band (C) component of the broadband signal 123 from passing tothe high-band path 127.

Referring now to the signal flow of the MoCA entry device 100 from thebroadband ports 115, the high-band ports 115 can receive one or morehigh-band signals 124 having a high frequency band (M) from one or morehigh-band devices 137. The high-band path 127 includes a high-bandsplitter 129 having a two or more terminals respectively connected tothe two or more high-band ports 115. The high-band splitter 131 combinesthe high-band signals 124 into a combined signal, which the high-bandsplitter provides as an input to the filter device 117. As describedpreviously herein, the filter device 117 passes the high frequency band(M) of the high-band signals to the broadband path 125, and blocks thehigh frequency band (M) from passing to the entry port 111. Inembodiments, the high-band filter 121 of the filter device 117 passesthe high frequency band (M) of the high-band signals to the broadbandpath 125, and the low-band filter 119 of the filter device 117 rejectsthe high frequency band (M). The broadband path 125 then passes thehigh-band signal 124 to the broadband ports 113A and/or 113B.Accordingly, the gateway device 135, the broadband device 136, and thehigh-band devices 137 can bidirectionally communicate via the highfrequency band (M) to form, for example, a MoCA network. However, thelow-band filter 119 prevents such signals for being communicated fromthe entry port 111, which prevents leakage of subscriber informationfrom the MoCA network from the premises 103 via the entry port 111.

As set forth in detail above, the MoCA entry device 100 is configuredsuch that the high-band filter 121 and/or high-band splitter 131 in thehigh-band path 127 substantially block signals outside the highfrequency band (M) of the high-band signals 124 (e.g., about 1125MHz-1675 MHz). As such, embodiments of the MoCA entry device 100disclosed herein optimize the high-band path 127 for the particular,limited frequency band of the high-band signals 124. Additionally, thehigh-band splitter 131 and/or the high-band path 127 operate only atfrequencies at or above 1000 MHz using components that minimize noise,reflection, power loss, leakage etc. over the high frequency band (M) ofthe high-band signals 124.

FIG. 1A shows a block diagram illustrating an example environment 10 inaccordance with aspects of the present disclosure. The environment 10includes a MoCA entry device 150, a premises 103, and a headend 107,which can be same or similar to those previously described. As also,previously described, the MoCA entry device 150 can be installed betweenthe premises 103 (e.g., a home or business of a CATV subscriber) and acable (e.g., COAX cable) connecting the headend 107 (e.g., aninfrastructure of a CATV service that provides high-definitionmultimedia content and broadband Internet service).

The MoCA entry device 150 includes an entry port 111, one or morebroadband ports 113A and 113B (e.g., CATV ports), and a multiplicity ofhigh-band ports 115 (e.g., MoCA ports), a filter device 117, a broadbandpath 125, a high-band path 127, a broadband splitter 129, and ahigh-band splitter 131 (such as a Wilkinson Splitter). These elementsand the signal flows among them can be the same or similar to thosepreviously described. Differently from the previous example shown inFIG. 1, the filter device 117 can include a low-pass filter (rather thanlow-band filter 119 and high-band filter 121) that connects the entryport 111 to the broadband path 125 and the high-band path 127. Inaccordance with some embodiments, the filter device 117 receives thesource signal 116 having the CATV frequency band (C) from the entry port111 and passes it to the broadband path 125 and the high-band path. Thelow-pass filter 150 that bidirectionally passes signals having the CATVfrequency band (C) and rejects any frequencies greater than the CATVfrequency band (C). Accordingly, in the reverse direction, the filterdevice 117 rejects the high frequency band (M) of the high-band signal124, included in the broadband signal 123. Doing so prevents leakage ofsubscriber information from the premises 103 via the entry port 111, aspreviously described.

Additionally, in accordance with some embodiments, the high-band path127 connects the broadband downstream ports 113 to the high-band ports115, and bidirectionally communicates high-band signals 124 having ahigh frequency band (M) (e.g., MoCA band signals) from the gatewaydevice 135 and/or the broadband device 136 to one or more high-banddevices 137 (e.g., MoCA devices) in the premises 103, and vice versa.The high-band path 127 includes high-band splitter 131. The high-bandsplitter 131 can include one or more devices that receive a broadbandsignal 123, including the source signal 116 from the filter device 117and high-band signals 124 from the gateway device 135, the broadbanddevice 136, and/or the high-band devices 137. In accordance with someembodiments, the high-band splitter 131 is constructed using one or morecomponents (e.g., transmission lines and/or splitters) optimized to passthe high frequency band (M) of the high-band signals 124, whilerejecting the frequency band (C) of source signal 116. For example, thehigh-band splitter 131 may operate only at frequencies using componentsthat minimize noise, reflection, power loss, leakage etc. over thefrequency range of the high-band path 127. In some embodiments, thehigh-band splitter 131 operates only at frequencies at or between 1100MHZ and 2000 MHz. Additionally, in some embodiments, the high-bandsplitter 131 operate only at frequencies at or between 1125 MHZ and 1675MHz. Accordingly, the high-band splitter 131 passes only the high-bandportion (M) of the broadband signal 123 to the high-band devices 137 viathe high-band ports 115. In the reverse direction, the high-bandsplitter 131 is configured to receive a number of high-band signals 124as inputs to a two or more terminals, combine such signals into acomposite high-band signal 124, and output the composite high-bandsignal 124 to the filter device 117 and the broadband path 125.

FIG. 2 shows an example of a MoCA entry device 200 in accordance withaspects of the present disclosure. The MoCA entry device 200 includesentry port 111, broadband downstream ports 113, high-band ports 115,filter device 117, low-band filter 119, high-band filter 121, broadbandpath 125, high-band path 127, broadband splitter 129, and high-bandsplitter 131, which can be the same or similar to those previouslydescribed herein. The low-band filter 119 passes a broadband signal 123by filtering a source signal 116 received from the entry port 111, aspreviously described herein, and outputs the broadband signal 123 to thebroadband splitter 129. In accordance with aspects of the presentdisclosure, the broadband splitter 129 can be one-input, two-outputsplitter optimized for an operational frequency range below 1675 MHz.

The high-band filter 121 passes a high-band signal 124 (e.g., a MoCAsignal) from one or more broadband devices (e.g., gateway device 135)connected via the broadband downstream ports 113, as previouslydescribed herein, to multiple (e.g., two or more) high-band ports 115through a network of one-input, two-output splitters 131A, 131B, and131C (collectively referred to herein as splitters 131). For example, asshown in FIG. 2, a first high-band splitter 131A can feed two high-bandsplitter 131B, which can each feed two more high-band splitter 131C, tooutput the high-band signal 124 to each of eight high-band ports 115. Inaccordance with aspects of the present disclosure, the high-bandsplitter 131 can be configured for an operational frequency range onlyabove 1125 MHz. And, in embodiments each of the high-band splitter 131can have a narrow operational frequency band between about 1125 MHz andabout 1675 MHz. Because each of the high-band splitter 131 only operateover such frequencies, the margin of tolerance and/or accuracy of thehigh-band splitter 131 minimizes error accumulation over the network ofhigh-band splitter 131. Notably, the number of high-band splitter 131illustrated in FIG. 2 is limited to eight for the sake of illustration.However, it is understood that the number of high-band ports 115 andsplitters 131 can be increased or decreased in implementationsconsistent with the present disclosure. For example, in embodiments, thehigh-band splitter 131A can feed two high-band splitter 131B to providefour outputs to each of four MoCA ports 115.

FIG. 3 shows an example of a MoCA entry device 300 in accordance withaspects of the present disclosure. The MoCA entry device 300, caninclude entry port 111, a single broadband port 113, multiple high-bandports 115, filter device 117, low-band filter 119, high-band filter 121,broadband path 125 high-band path 127, and high-band splitter 131, whichcan be the same or similar to those previously described herein.Differently from the previous embodiments, the broadband path 125 lacksany broadband splitter (e.g., broadband splitter 129). Rather, thelow-band filter 119 directly connects to the single broadband port 119via the broadband path 125, which feeds the broadband signal 123 tosingle broadband device (e.g., a gateway device 135). Thus, inaccordance with aspects of the present disclosure, the broadband path125 is simplified by reducing components (e.g., CATV band splitters),which also reduces cost and complexity of the MoCA entry device 300.Further, because the broadband path 125 lacks any splitter, the MoCAentry device 300 minimizes attenuation of the source signal 116 and thebroadband downstream signal 123.

FIG. 4 shows an example of a MoCA entry device 400 in accordance withaspects of the present disclosure. The MoCA entry device 400 includesentry port 111, broadband ports 113, high-band ports 115, filter device117, low-band filter 119, high-band filter 121, broadband path 125, ahigh-band path 127, and high-band splitter 131, which can be the same orsimilar to those previously described herein. Differently, the broadbandpath 125 includes a directional coupler 405 including an input port (E)connected to the filter device 117, a through port (T) connected tobroadband port 113A, and a coupled port (C) connected to broadband port113B. The input port (E) passes a majority of the power of broadbandsignal 123 to broadband port 113A. For example, the directional coupler405 can attenuate the broadband signal 123 by less than one decibel (dB)between the input port (E) and the through port (T). In comparison, thedirectional coupler 405 can attenuate the broadband signal 123 providedto the broadband port 113B by over 6 dB between the input port (E) andthe coupled port (C). In accordance with aspects of the presentdisclosure, the directional coupler 405 allows connection to a telephonedevice (e.g., a voice-over-internet protocol (VOIP) device) connected tobroadband port 113B that is unaffected by reflections from an activedevice (e.g., a gateway device) that may be connected to broadband port113A. Additionally, the directional coupler 405 can allow the telephonedevice connected to broadband port 113B to communicate in situationswhen power to a subscriber residence is lost.

FIG. 5 shows an example of a MoCA entry device 500 in accordance withaspects of the present disclosure. The MoCA entry device 500 includesentry port 111, broadband downstream ports 113A . . . 113 n, high-bandports 115, filter device 117, low-band filter 119, high-band filter 121,broadband path 125, high-band path 127, and high-band splitter 131,which can be the same or similar to those previously described herein.Differently, the broadband path 125 includes a one-to-n broadbandsplitter 505 having n terminal respectively connected to broadband ports113A . . . 113 n, wherein n can be any integer value greater than two(2). Thus, in accordance with aspects of the present disclosure, thebroadband path 125 can be customized to connect to any number ofbroadband devices (e.g., gateway device 135 and or broadband device 136)in a subscriber premises.

FIG. 6 shows an example of a MoCA entry device 600 in accordance withaspects of the present disclosure. The MoCA entry device 600 can includeentry port 111, broadband ports 113, high-band ports 115, broadband path125, and high-band path 127, which can be similar to those previouslydescribed herein. Different from embodiments previously describedherein, the MoCA entry device 600 includes an isolation filter 605 and areflection filter 630, that can be separated (e.g., distributed) in theMoCA entry device 600, rather than combined in a single filter device(e.g., filter device 117). The isolation filter 605 rejects the highfrequency band (M) so as to prevent leakage of high-band signals 124from the entry port 111. Thus, the isolation filter 605 can providepoint of entry isolation, while allowing source signal 116 to pass to asplitter 610 in the broadband path 125. In some embodiments, theisolation filter 605 is a low pass filter that only passes frequenciesbelow 1100 MHz. In other embodiments, the isolation filter 605 onlypasses frequencies below 1000 MHz, such as low-band frequency (C). Thereflection filter 630 can be a filter device that may include high passand low pass elements, as detailed below.

In implementations, the reflection filter 630 can balance power betweenthe broadband ports 113 and the high-band ports 115 by reflecting aportion of the power of high-band signals 124 in the high-band path 127back to the high-band ports 115. In some implementations, the reflectionfilter 630 rejects the low frequency band (C) (e.g., CATV frequencybands) using a combination of high pass filtering and the low frequencyfiltering inherently provided by high band splitters and transmissionlines. Additionally, the reflection filter 630 can throttle the power ofthe high-band signal 124. Doing so allows the reflection filter 630 todecrease the power of the high-band signal 124 transmitted from thehigh-band path 127 to the broadband path 123, while increasing power atall of the high-band ports 115 in the high-band path 127.

In accordance with aspects of the present disclosure, the entry port 111can provide the source signal 116 having a frequency band (C) to theisolation filter 605. After passing through the isolation filter 605,the source signal 116 is split between the broadband bath 125 and thehigh-band path 127 at circuit node 635. In the broadband path 125, asplitter device 610 connects the isolation filter 605 of the filterdevice 117 (and the reflection filter 630 of the high band path) to thebroadband ports 113. The splitter device 610 includes terminal (E),terminal (A), and terminal (B). The terminal (E) receives the sourcesignal 116 having CATV frequency band (C) as an input from the isolationfilter 605 and the high-frequency band (M) as an input from the hybridfilter 630. The splitter 610 splits the source signal 116 and outputssuch signal via terminal (A) and terminal (B), which connect to thebroadband ports 113.

In the reverse direction from the broadband ports 113, one or more ofthe terminals (A or B) of the splitter device 610 receives the broadbandsignal 123 having frequency bands (C) and (M) as an input from thebroadband ports 113 and 113. The low-band signal (C) portion of thebroadband signal 123 can pass through isolation filter 605 to the entryport 111, whereas the isolation filter blocks the high-band (M) portionfrom passing to the entry port 111. Additionally, at circuit node 635,the broadband signal 123 can flow to the high-band path 127 via thereflection filter 630, which allows the high-frequency band (M) to passto the high-band ports 115. Accordingly, a broadband device (e.g.,gateway device 135 or broadband device 136) connected to broadband port113 can bidirectional communicate with high-band devices (e.g.,high-band devices 137) connected to the high-band port 115 and to asource connected to entry port 111 via the splitter device 610.

In the direction from the high-band ports 115, one or more of thehigh-band ports 115 can receive the high band signals 124. The high-bandsignals 124 can be shared among the high-band ports 115 via splitters131. Additionally, the high-band signal 124 can be communicated to thecircuit node 635 via the reflective filter 630. As described previously,the high-band signal 124 can be communicated to the broadband ports 113via the splitter 620, whereas they are blocked from the entry port 111by the isolation filter 605. Further, as described above, the reflectionfilter 630 can throttle the amount of power of the high-band signal 127exiting the high-band path 127 so as to increase the signal power of thesignal communicated among the high-band ports.

FIG. 6A shows a block diagram of an example of a reflection filter 630in accordance with aspects of the present disclosure. The reflectionfilter 630 can include a high-pass filter 650 and a low-pass filter 655that filter low-band frequencies (e.g., low band frequency (C). Thehigh-pass filter 650 can be a resistive-captive-type high-pass filterand the low-pass filter 655 can be an inductive-type low-pass filter. Insome embodiments, the low-pass filter 655 can be a high-band reflector(or low pass element) that throttles the signal strength of thehigh-band signal 124 to attenuate a high-band signal 124 bidirectionallypassing through the reflection filter 630. Doing so allows thereflection filter 630 to decrease the power of the high-band signal 124transmitted from the high-band path 127 to the broadband path 123, whileincreasing power at all of the high-band ports 115 in the high-band path127. For example, because the path between the high-band path 127 to thebroadband path 123 is low loss (e.g., 6 dB) and the loss betweenadjacent high-band ports 115 is high (e.g., 25 dB), the low-pass filter655 can reflect the high-band signal 124 flowing to the broadband path123 and, instead, distribute its power among the high-band ports,thereby increasing signal strength at the high-band parts 115.

While various aspects and embodiments have been disclosed herein, otheraspects and embodiments will be apparent to those skilled in the art.The various aspects and embodiments disclosed herein are for purposes ofillustration and are not intended to be limiting, with the true scopeand spirit being indicated by the following claims. The presentdisclosure is not to be limited in terms of the particular embodimentsdescribed in this application, which are intended as illustrations ofvarious aspects. Many modifications and variations can be made withoutdeparting from its spirit and scope, as will be apparent to thoseskilled in the art. Functionally equivalent apparatuses within the scopeof the disclosure, in addition to those enumerated herein will beapparent to those skilled in the art from the foregoing descriptions.Such modifications and variations are intended to fall within the scopeof the appended claims. The present disclosure is to be limited only bythe terms of the appended claims, along with the full scope ofequivalents to which such claims are entitled. It is also to beunderstood that the terminology used herein is for the purpose ofdescribing particular embodiments only, and is not intended to belimiting.

With respect to the use of substantially any plural and/or singularterms herein, those having skill in the art can translate from theplural to the singular and/or from the singular to the plural as isappropriate to the context and/or application. The varioussingular/plural permutations may be expressly set forth herein for sakeof clarity.

It will be understood by those within the art that, in general, termsused herein, and especially in the appended claims (e.g., bodies of theappended claims) are generally intended as “open” terms (e.g., the term“including” should be interpreted as “including but not limited to,” theterm “having” should be interpreted as “having at least,” the term“includes” should be interpreted as “includes but is not limited to,”etc.). It will be further understood by those within the art that if aspecific number of an introduced claim recitation is intended, such anintent will be explicitly recited in the claim, and in the absence ofsuch recitation no such intent is present. For example, as an aid tounderstanding, the following appended claims may contain usage of theintroductory phrases “at least one” and “one or more” to introduce claimrecitations. However, the use of such phrases should not be construed toimply that the introduction of a claim recitation by the indefinitearticles “a” or “an” limits any particular claim containing suchintroduced claim recitation to embodiments containing only one suchrecitation, even when the same claim includes the introductory phrases“one or more” or “at least one” and indefinite articles such as “a” or“an” (e.g., “a” and/or “an” should be interpreted to mean “at least one”or “one or more”); the same holds true for the use of definite articlesused to introduce claim recitations. In addition, even if a specificnumber of an introduced claim recitation is explicitly recited, thoseskilled in the art will recognize that such recitation should beinterpreted to mean at least the recited number (e.g., the barerecitation of “two recitations,” without other modifiers, means at leasttwo recitations, or two or more recitations). Furthermore, in thoseinstances where a convention analogous to “at least one of A, B, and C,etc.” is used, in general such a construction is intended in the senseone having skill in the art would understand the convention (e.g., “asystem having at least one of A, B, and C” would include but not belimited to systems that have A alone, B alone, C alone, A and Btogether, A and C together, B and C together, and/or A, B, and Ctogether, etc.). In those instances where a convention analogous to “atleast one of A, B, or C, etc.” is used, in general such a constructionis intended in the sense one having skill in the art would understandthe convention (e.g., “a system having at least one of A, B, or C” wouldinclude but not be limited to systems that have A alone, B alone, Calone, A and B together, A and C together, B and C together, and/or A,B, and C together, etc.). It will be further understood by those withinthe art that virtually any disjunctive word and/or phrase presenting twoor more alternative terms, whether in the description, claims, ordrawings, should be understood to contemplate the possibilities ofincluding one of the terms, either of the terms, or both terms. Forexample, the phrase “A or B” will be understood to include thepossibilities of “A” or “B” or “A and B.” In addition, where features oraspects of the disclosure are described in terms of Markush groups,those skilled in the art will recognize that the disclosure is alsothereby described in terms of any individual member or subgroup ofmembers of the Markush group.

What is claimed is:
 1. A passive, Multimedia over Coax Alliance (MoCA)entry device comprising: an entry port configured to communicate cabletelevision (CATV) signals with a provider; a broadband port configuredto communicate the CATV signals with a gateway device at a premises; aplurality of high-band ports configured to communicate MoCA signals witha plurality of MoCA devices at the premises; a filter device comprisinga low-band filter and configured to block the MoCA signals from theentry port; a broadband path connecting the broadband port to the entryport and the plurality of high-band ports, the broadband path beingconfigured to communicate the CATV signals between the broadband portand the entry port, and to communicate the MoCA signals between with thebroadband port and the plurality of high-band ports; and a high-bandpath connecting the plurality of high-band ports to the broadband port,the high-band path being configured to pass only the MoCA signals to theplurality of high-band ports.
 2. The MoCA entry device comprising ofclaim 1, wherein: the filter device comprises a low-pass filter and ahigh-pass filter; the low-pass filter is configured to pass the CATVsignals to the entry port and to block the MoCA signals from the entryport; and the high-pass filter is configured to block the CATV signalsfrom the plurality of high-band ports and to block the CATV signals fromthe plurality of high-band ports.
 3. The MoCA entry device of claim 1,wherein the broadband port is the sole broadband port included in theMoCA entry device.
 4. The entry device of claim 1, wherein the broadbandpath comprises a directional coupler configured to split the CATVsignals between the broadband port and a second broadband port.
 5. TheMoCA entry device of claim 1, wherein the high-band path comprises ahigh-band splitter configured to only pass the MoCA signals.
 6. The MoCAentry device of claim 1 wherein the filter device comprises a diplexer.7. A radio-frequency (RF) entry device comprising: a filter deviceconfigured to communicate low-band RF signals with an entry port; abroadband path configured to communicate broadband RF signals with abroadband port; and a high-band path configured to communicate pluralityof high-band RF signals with a plurality of high-band ports, wherein:the filter device is configured to block communication of any RF signalshaving frequencies greater than a frequency band of the low-band RFsignals, the high-band path is configured to reject any RF signalshaving frequencies less than a frequency band of the high-band RFsignals, and the broadband path is configured to pass RF signals havingfrequencies in the frequency bands of the low-band RF signals and thehigh-band RF signals.
 8. The RF entry device of claim 7, wherein: thefrequency band of the low-band RF signal is below about 1000 megahertz(MHz); and the frequency band of the high-band RF signal is betweenabout 1000 MHz and about 2000 MHz.
 9. The RF entry device of claim 7,wherein the filter device comprises a diplexer configured to: receivethe broadband RF signals from the broadband path; provide a low-bandportion of the broadband RF signal to the entry port; and provide ahigh-band portion of the broadband RF signal to the high-band path. 10.The RF entry device of claim 7, wherein: the broadband path isconfigured to communicate the broadband RF signals with the filterdevice and the high-band path; the filter device is configured to pass alow-band portion of the broadband RF signals to the entry port, and toblock a high-band portion of the broadband RF signals from the entryport; and the high-band path is configured to pass a high-band portionof the broadband RF signals to the plurality of high-band ports, and toblock the low-band portion of the broadband RF signals from theplurality of high-band ports.
 11. The RF entry device of claim 7,wherein the filter device comprises: a first filter configured to onlypass frequencies below about 1000 MHz; and a second filter configured toonly pass frequencies above 1000 MHz.
 12. The RF entry device of claim7, wherein the broadband port is the sole broadband port included in theMoCA entry device.
 13. The RF entry device of claim 7, wherein thebroadband path comprises a directional coupler configured tobidirectionally communicate the broadband RF signals to a firstbroadband device and a second broadband device.
 14. The RF entry deviceof claim 7, wherein the high-band path comprises a high-band splitterconfigured to only pass a frequency band from about 1000 MHz to about2000 MHz.
 15. A device comprising: an entry port; a broadband port; aplurality of high-band ports; a filter device; a broadband pathconnecting the entry port to the broadband port; and a high-band pathconnecting the broadband port to the plurality of high-band ports;wherein: the broadband path is configured to provide a low-band signalfrom the broadband port to the filter device; and the high-band path isconfigured to provide a high-band signal to the broadband path and toreject the low-band signal from the broadband path; the filter deviceconfigured to block frequencies of the high-band signal from the entryport.
 16. The entry device of claim 15, wherein: the entry port isconfigured to receive a source signal from a source via a network; andthe broadband port is configured to provide the source signal to abroadband device in a premises; and the plurality of high-band ports areconfigured to provide the high-band signal to a plurality of high-banddevices in the premises.
 17. The entry device of claim 16, wherein: theentry device is a passive, enhanced Multimedia over Coax Alliance (MoCA)entry device; the entry port is an upstream port of the entry devicethat receives the source signal from a headend of a cable televisionprovider; the broadband device is a cable gateway device; and theplurality of high-band devices are MoCA devices.
 18. The entry device ofclaim 15, wherein: the filter device comprises a low-band filter and ahigh-band filter; the low-band filter is configured to rejectfrequencies greater than about 1000 MHz; and the high-band filter isconfigure to reject frequencies less than about 1125 MHz.
 19. The entrydevice of claim 15, wherein the high-band path comprises a plurality ofhigh-band splitters configured to operate only at frequencies betweenabout 1000 MHz and about 2000 MHz.
 20. The entry device of claim 15,further comprising a reflection filter separate from the filter deviceand located between the broadband port and the plurality of high-bandports, the reflection filter configured to reflect a high-band signalreceived via one of the plurality of high-band ports to all of theplurality of high-band ports and to attenuate a high-band signalbidirectionally passed between the broadband path or the high band path.